Method and system for managing a plurality of enterprise business systems

ABSTRACT

An enterprise business process management system and method for definition and execution of business processes formed from portions of one or more business applications present in an enterprise. The enterprise business process management system includes a server, a router, and an interface for defining and executing such business processes. A data quality business process detects, corrects, analyzes, and reports quantitative and qualitative characteristics of application data and transactional data present in the enterprise. An interface module is provided by which a user may select and define function definition information for a business process.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application relies for priority on U.S. Provisional PatentApplication No. 60/496,924, entitled “METHOD AND SYSTEM FOR MANAGING APLURALITY OF ENTERPRISE BUSINESS SYSTEMS,” which was filed on Aug. 22,2003, the entire contents of which are incorporated herein by reference.

This application is related to U.S. Provisional Patent Application Ser.No. 60/366,547, filed on Mar. 25, 2002, entitled “Method and System forEnterprise Data Quality Management.” It is also related to U.S.Non-Provisional patent application Ser. No. 10/396,134, filed on Mar.25, 2003, entitled “Method and System for Enterprise Business ProcessManagement.” The contents of both of these related applications isincorporated herein by reference.

This disclosure contains information subject to copyright protection.The copyright owner has no objection to the facsimile reproduction byanyone of the patent disclosure or the patent as it appears in the U.S.Patent and Trademark Office files or records. However, the ownerreserves all remaining copyrights associated with the inventiondescribed herein, including all copyrights in the screen displaysprovided herein to facilitate an understanding of the invention.

BACKGROUND OF THE INVENTION

1. Field of the Invention

Embodiments of the present invention relate generally to businessprocess management and, more particularly, to methods and systems forcomputer-based business process management.

2. General Background and Description of Related Art

The automated processing of information has been an enormous benefit tobusinesses because it has greatly reduced the cost of certain tasks.Every enterprise regardless of whether it is a government, commercialbusiness or not-for-profit organization has the operational necessity tomanage information.

This information is used to acquire customers, input orders, shipproduct, bill customers, collect invoices, pay employees and vendors,order product, audit inventory and maintain records of transactionsbetween employees, customers and suppliers, for example, in the case ofa commercial business.

In the normal course of events, information is acquired, processed andconsolidated utilizing software, computer hardware and digital networksin accordance with each organization's internal operational model.

Unfortunately, the automated processing of information has also createdseveral problems for businesses, especially where the information in thecompany's data store is incorrect. Automated processing of incorrectinformation carries a high cost for businesses in and of itself. Inaddition, the time, effort, and expense required to correct theundesired results can significantly impact an organization's resources.

Typical examples of the impact of errors on an organization include:

-   -   (1) Recipients receive multiple copies of the same offers in the        mail, which may result in: (a) the sender wasting postage and        printing, and (b) the recipient being negatively affected by        waste and, as a result, not ordering products;    -   (2) Postal systems and other message and package shippers are        unable to deliver a significant percentage of their material to        the intended recipients, which may have the result that: (a) the        product is not delivered on time and returned to shipper due to        inaccurate address, (b) costly efforts being made to determine        the correct address and repack and reship the product, (c) the        invoices are returned and not paid on time or at all, (d) costly        efforts are made to determine correct address and resend        invoice, (e) clients become annoyed by poor service and, as a        result, switch to another vendor, if possible, and (f) customer        service, billing, collections, shipping all require additional        resources to perform their functions;    -   (3) Individual operational units contain inaccurate information        on clients as well, which may have the result that: (a)        enterprise efforts at consolidating information are incomplete,        costly and prolonged, and (b) errors in individual operational        units, when consolidated, compound the overall error rates and        impair the ability for meaningful analysis;    -   (4) Incomplete and inaccurate information is consolidated in        data warehouses, data marts, operational data stores, customer        information files and centralized data stores for CRM, ERP, SCM        and other centralized processes, which may result in: (a)        marketing not being unable to accurately forecast the value and        potential of individual clients and client segments and losing        valuable market opportunity, (b) customer service not being able        to provide the proper service and, as a result, losing clients        due to dissatisfaction with service, and (c) fraud not being        detected in a timely fashion, resulting in the enterprise being        defrauded of large amounts of money;    -   (5) Operational units are unable to determine the correct tax        jurisdiction and tax assignment, which may result in: (a) the        enterprises not charging the right tax to the client and paying        the right amount to the right authority, (b) taxing authorities        not collecting all the proper taxes due them, (c) consumers        paying more taxes than they should, and (d) corporations        suffering liabilities with tax jurisdictions and clients; and    -   (6) Customers are unhappy and move to a competitive service.

The impact of erroneous information on a company's revenue is easilyexplained using a typical mass mailing as an example. Naturally, this isbut one example, as the list presented above identifies a number ofother potential impacts on a company's revenue.

Companies generate customer lists in a variety of ways. Informationcollected by one part of an enterprise is often used by other parts ofan organization to perform their functions. If the company has a retailcomponent and a catalog component, customer information may be enteredinto the company's data store at the retail location, at the cataloglocation, or even through the Internet. Each of these three entrypositions presents a location where the information may be erroneous orduplicative of pre-existing information. Any error in the accuracy ofinformation as it is collected, processed and consolidated can impactthe effectiveness of multiple functions within an enterprise.

It is possible that a customer may have customer information enteredcorrectly at the retail level. Subsequently, the customer may make apurchase through the catalog division. At that time, the data entryspecialist may, for example, enter the customer's name into the datastore incorrectly (e.g., by misspelling the person's last name). Onstill another occasion, the same customer may make a purchase throughthe Internet. At that time, the customer will be required to supply hisor her information for a third time. In this situation, assume that thecustomer typed his or her last name incorrectly. Therefore, in thisscenario, the customer information has been entered three times, two ofwhich were incorrect.

Relying on its stored data, the company then prints and sends an updatedcopy of its catalog to its customers. Since the customer described hasthree separate entries in the business's data store, the customerreceives three copies of the same catalog. As is easily understood, thecost to the company of printing and mailing the catalog has been tripledsimply because of errors in the company's data store.

The problem of data quality exists with many businesses. In the priorart, there have been several approaches offered to minimize the dataquality problem.

Previous approaches to data quality include providing a variety ofvendor-specific or application-specific functions to the business. Thedata quality functions are designed specifically to automatically reviewa company's data, identify errors, in some cases, and correct thoseerrors. To do this in such a way that is flexible to differentbusinesses, the data quality functions typically provide severalsettings that may be adjusted by businesses to meet their individualneeds.

Typically, businesses select a standardized set of settings for aparticular data quality function that the business finds mostbeneficial. The settings may, for example, remove the errors in a datastore to “clean” the data store to a point where the data is 95%accurate (which is considered to be a very good result).

The problem of data quality is compounded when a company includesmultiple units, each of which have separate data stores that containoverlapping information, and the company tries to create a consolidateddata store.

In the example presented above, the company had three businesscomponents, a retail component, a catalog component, and an Internetcomponent, each of which contained a separate customer information datastore. Typically, if each component wished to “clean” up its data, eachcomponent would purchase a data quality solution and apply that solutioninternally. If each component were to produce a data store that was 95%accurate, the result would be considered quite good.

If the company then tries to create a consolidated data store, a problemarises in that the errors in each data store compound one another. Inthe case presented, each data store has the same error. The combineddata store will have an error rate of 0.95×0.95×0.95=0.857375. Thismeans that the resulting data store has an error rate of about 15%,three times higher than each of the data stores that were combined. Asmay be appreciated, this problem is particularly pronounced when four ormore data stores are combined together.

Furthermore, because the vendor-specific and application-specific dataquality functions have unique strengths and weaknesses in detectingand/or correcting errors, the errors may be inadvertently propagatedthroughout the enterprise as applications pass data back and forth. Thismay have the undesirable result of causing a multiplicative increase inthe overall error rate for the enterprise as a whole.

While data quality solutions are beneficial to the operation ofbusinesses, they are limited in their ability, especially in cases wherecompanies try to create centralized data stores for multiple businessentities in an enterprise or group of entities.

Moreover, when a business desires to develop a program to “clean up” itscentralized data store, current doctrine dictates that the businessretain a firm to develop the appropriate software. The development ofsoftware follows what is commonly referred to as the SoftwareDevelopment Life Cycle (SDLC).

The known SDLC adhered to by developers of business processes, such as,for example, data quality processes, results in a time and resourcecostly lock-step sequential phase approach. For example, a known SDLCincludes the following phases which are performed sequentially:requirements definition, general design, detailed design, development,testing, quality assurance checking, trial, implementation, andmaintenance/modification. In addition, different personnel or serviceproviders with different skill sets may be required as the project movesfrom phase to phase. For example, a systems engineer or business analystmay be required during the requirements analysis/definition and testphases, but a software engineer may be required for the design phases.Project handoff between phases introduces errors into the final productand adds cost due to increased project time, increased overhead, andhigher project headcount.

Still further, because the requirements definition phase may bearbitrarily halted (i.e., requirements “frozen”) in order to permitdesign activities to begin, the known SDLC is inflexible andunaccommodating to the evolving needs of customers for softwareproducts.

The failings identified above with respect to the prior art cry out fora solution.

SUMMARY OF THE INVENTION

It is, therefore, one aspect of the present invention to provide abusiness process management system and method that resolves many of thedeficiencies in the prior art.

An enterprise business process management system may include anenterprise business process server coupled to one or more clients, arouter, and an interface module. In particular, at least one embodimentof an enterprise business process management system in accordance withthe present invention may include an enterprise business process servercapable of receiving data from at least one client, at least one routeraccessible by the enterprise business process server, and at least onebusiness process accessible by the at least one router. The enterprisebusiness process server may be configured to access the at least onebusiness process via the router, to execute the at least one businessprocess on at least a portion of the client data, and to generatebusiness process output data as a function of the at least one businessprocess. The enterprise business process management system may furtherinclude an interface accessible by the enterprise business processserver which operates with the enterprise business process server tooutput a process designer interactive page. The process designerinteractive page may be configured to accept instructions concerning theat least one business process, to generate process information data, andto provide the process information data to the enterprise businessprocess server. Furthermore, the enterprise business process server maybuild an instruction set for the business process based upon the processinformation data.

In accordance with at least one embodiment of the invention, anenterprise data quality management system and method are provided thatdetermine, analyze, enhance, and report qualitative and quantitativeaspects of application data and transactional data present in theenterprise.

In accordance with other aspects of the present invention, error reportsmay be provided at various levels of data processing to identify wheredata errors are made.

The system and method also provides for a variety of graphical views topresent information concerning where errors are made so that businessesmay avoid and correct (or at least minimize) those errors in the future.

Furthermore, embodiments of the present invention may provide for ashortened SDLC in which several of the known SDLC steps are combinedsuch that project development time is shortened and the processsimplified, resulting in significant time and cost savings.

For example, in one embodiment, the requirements definition, generaldesign, detailed design, and development phases may be accomplishedsimultaneously in a single phase utilizing an interactive processdesigner.

Moreover, in one embodiment of the invention, by applying test data tothe business processes defined and implemented as described herein, theknown SDLC test, quality assurance, and trial phases may be accomplishedin a single phase.

In addition, in an embodiment of the invention, each of the SDLCactivities may be accomplished through user interaction with one processdesigner interface provided by a single product.

Furthermore, in an embodiment of the invention, a software engineer maynot be required for coding during the project.

Still further, embodiments of the present invention may allow for thereuse of functions from multiple software applications, as well asproviding the capability for the user to define a new or modifiedfunction of a business process. In at least one embodiment, each suchfunction may be maintained in a function registry or function libraryand made available to a business process server for subsequent use indefining additional business processes or modified business processes.

Still further, embodiments of the present invention may provide anenterprise to use “best of breed” business processes in combination toachieve increased effectiveness for the overall process. Portions ofmultiple different business applications may be combined to form a newor modified business process in which the portions are chosen for aparticular effect or other such criteria resulting in increased overalleffectiveness. For example, several data quality processes, each ofwhich may be obtained from the same or multiple different businessapplications, may be defined to comprise a single data quality businessprocess that achieves a higher overall data accuracy percentage thanwould be possible applying each of the multiple data quality businessapplications alone.

Still other aspects of the invention will be made apparent from thedescription that follows and the drawings appended hereto.

BRIEF DESCRIPTION OF THE DRAWINGS

The benefits of the present invention will be readily appreciated andunderstood from consideration of the following detailed description ofat least one exemplary embodiment of this invention, when taken with theaccompanying drawings, in which:

FIG. 1 is an illustrative diagram of a system implementing or employedby the enterprise business process management system in accordance withat least one exemplary embodiment of the invention;

FIG. 2 is a schematic block diagram of equipment that may be used toimplement a server designed in accordance with at least one embodimentof the invention;

FIG. 3 illustrates a functional block diagram of an enterprise dataquality application of the enterprise business process server inaccordance with at least one embodiment of the invention;

FIG. 4 is a functional block diagram illustrating the relationship amongdata sources/destinations, products, and processes in one embodiment ofthe invention;

FIG. 5 is a functional block diagram illustrating equipment that may beused to implement a system in accordance with at least one embodiment ofthe invention;

FIG. 6 is a flow chart illustrating a method used by the enterprisebusiness process management system in accordance with at least oneexemplary embodiment of the invention;

FIG. 7 is an example of an error report for an executive view accordingto at least one embodiment of the invention;

FIG. 8 is an example of an error report for a customer support viewaccording to at least one embodiment of the invention;

FIG. 9 is an example of an error report for an individual view accordingto at least one embodiment of the invention;

FIG. 10 is an example of an error report for a manager view according toat least one embodiment of the invention;

FIG. 11 is a flow chart of a method of establishing a business processfor the enterprise business process management system in accordance withat least one exemplary embodiment of the invention;

FIG. 12 is an exemplary user interaction page of a graphical userinterface for creating a business process in accordance with at leastone embodiment of the invention;

FIG. 13 is an exemplary user interaction page of a graphical userinterface for adding a data source for a process in accordance with atleast one embodiment of the invention;

FIG. 14 is an exemplary user interaction page of a graphical userinterface for defining an input packet for a process in accordance withat least one embodiment of the invention;

FIG. 15 is an exemplary user interaction page of a graphical userinterface for defining an output packet for a process in accordance withat least one embodiment of the invention;

FIG. 16 is an exemplary user interaction page of a graphical userinterface for selecting a product to a process in accordance with atleast one embodiment of the invention;

FIG. 17 is an exemplary user interaction page of a graphical userinterface for adding a product for use with a process in accordance withat least one embodiment of the invention;

FIG. 18 is an exemplary user interaction page of a graphical userinterface for selecting a data destination for a process in accordancewith at least one embodiment of the invention;

FIG. 19 is an exemplary user interaction page of a graphical userinterface for establishing a process in accordance with at least oneembodiment of the invention;

FIG. 20 shows an example process designer interface interactive displayfor a graphical user interface provided in accordance with at least oneembodiment of the invention;

FIG. 21 shows a series of build files utilized in an embodiment of theinvention by the enterprise business process server to build a codeimplementation of a business process;

FIG. 22 illustrates a method of building a new router dynamic linklibrary in an embodiment of the invention;

FIGS. 23 a-d are a flow chart illustrating a method of implementing abusiness process in accordance with at least one embodiment of theinvention;

FIG. 24 provides a functional block diagram showing the relationshipamong functions, processes and products (e.g., tools) involved in thedefinition of business processes in an embodiment of the invention;

FIG. 25 shows an example of a functions overview interactive pageprovided in an embodiment of the invention;

FIG. 26 shows an example of a process definition area portion of aprocess designer interactive page provided in an embodiment of theinvention;

FIG. 27 shows an example interactive page illustrating adding an elementof a process step from the function library in an embodiment of theinvention;

FIG. 28 shows an example interactive page illustrating linking ofprocess steps in the process definition area of a process designerinteractive page in an embodiment of the invention;

FIG. 29 shows an example interactive page portion by which a conditionalstatement may be defined for an element of a process step according toat least one embodiment of the invention;

FIG. 30 shows an example of a products definition interactive pageprovided in an embodiment of the invention;

FIG. 31 shows an example of a data destination definition interactivepage provided in an embodiment of the invention;

FIG. 32 shows an example of a products selection interactive pageprovided in an embodiment of the invention;

FIG. 33 shows an example of the content of a function template file pageprovided in an embodiment of the invention;

FIG. 34 shows an example of a function settings interactive pageprovided in an embodiment of the invention;

FIG. 35 shows an example process tester interactive page according to anembodiment of the invention;

FIG. 36 shows an illustration of a data-populated design area of aprocess tester interactive page in an embodiment of the invention;

FIG. 37 shows an example of a connection definition interactive pageaccording to at least one embodiment of the invention;

FIG. 38 illustrates a comparison business process in accordance with anembodiment of the invention;

FIG. 39 shows the relationship between the interface module, enterprisebusiness process server, and router in an embodiment of the invention;

FIG. 40 is a schematic diagram illustrating the connection between aglobal management system and a local client server and enterprisebusiness process server;

FIG. 41 is a schematic diagram of the connection between a globalmanagement system and two local management systems, illustrating thecommunication links therebetween; and

FIG. 42 is a schematic illustration showing the individual librarieswithin local management servers and the integrated library within theglobal management server.

DETAILED DESCRIPTION OF THE INVENTION

While the present invention will be described in connection withexemplary embodiments thereof, the exemplary embodiments are notintended to be limiting of the invention. On the contrary, alternatives,modifications and equivalents of the described examples are alsointended to be included within the spirit and scope of the invention,which is defined in part by the claims appended hereto.

In accordance with at least one embodiment of the invention, anenterprise business process management system and method are provided.Although at least one embodiment is presented herein in the form of anembodiment of an enterprise data quality management system, it is to beunderstood that the teachings herein may be applied more generally toany enterprise business process management system, including or inaddition to those business processes involved in data qualitymanagement. The system and method may utilize a server and aninterchangeable router for defining, building and executing steps inbusiness processes, including, for example, steps for detecting,correcting and reporting data errors present in various applicationsthroughout an enterprise. An enterprise may include multiple computingnodes located in different geographic or physical locations thatcomprise a business organization. The various computing nodes may beinterconnected for inter-node communication throughout the enterpriseusing a network such as, but not limited to, an intranet, the Internet,leased telephone or data lines, a wireless network, or any combinationof these. Connected in any of these manners, among others, usersassociated with the enterprise may obtain transparent, virtual access toenterprise applications, processes, and functions regardless of thephysical location of the node or nodes where the applications,processes, and functions reside.

FIG. 1 is an illustrative diagram of a system implementing or employedby the enterprise business process management system in accordance withat least one exemplary embodiment of the invention. Referring to FIG. 1,an enterprise business process management system 100 may include anenterprise business process server 101 coupled to one or more additionalclients such as, but not limited to, an Extract, Transform and Load(ETL) client 102, an Enterprise Application Integration (EAI) client103, an Enterprise Resource Planning (ERP) client 104, and a CustomerRelationship Management (CRM) client 105. The enterprise businessprocess server 101 may also be coupled to further additional clientssuch as a Supply Chain Manager (SCM) client (not shown). Each of theadditional clients may include at least one business application.Furthermore, the enterprise business process server 101 may also becoupled to an information data store 106 and a flat files data store107, one or more mainframes 108, and the Internet 109. In at least oneembodiment, the enterprise business process server 101 may also becoupled to one or more terminals such as a call center terminal(s) 110,data entry terminals 111, local user terminal(s) 112, and remote userterminal(s) 113. In at least one embodiment, the enterprise businessprocess server 101 may be an enterprise data quality server or anenterprise business process server configured to allow for thedefinition and execution of enterprise data quality management.

The enterprise business process server 101 may communicate withenterprise nodes including the additional clients 102-105, the datastores 106 and 107, mainframes 108, Internet 109 and terminals 110-113using a variety of communications networks including, but not limitedto, a network of interconnected networks such as the Internet, a LocalArea Network (LAN), a Wide Area Network (WAN), an intranet including anyof these, and/or the PSTN, a wireless network, or any combinationthereof. In at least one embodiment, the enterprise business processserver 101 may communicate with one or more of these enterprise nodesfor receiving and transmitting transaction related data as well as errorreports, at a minimum.

Generally, the clients 102-105 may be any data source that can send orreceive data such as, but not limited to, a server, or a client portionof a client-server application. A client may host one or more businessapplications processes, or functions of the enterprise, for example.Clients may be located internal or external to an enterprise firewall.

The ETL client 102 may be configured to enable an organization toextract data sets from one data source, map the data to another datasource, transform the data if necessary, consolidate data sources, andload the data into the destination source or sources. Such an ETL client102 may be primarily batch processing oriented and utilize a hubarchitecture in which the transformations and mappings are performed asthe data is passed from its source to its destination.

The EAI client 103 may be configured to enable enterprise transactionsto pass from one application to another within anorganization/enterprise and from one organization to a partnerorganization that exists on an EAI network. Such an EAI client 103 mayuse a hub architecture and include capabilities for mapping andtransforming data associated with the enterprise transactions.

The ERP client 104 may be configured to integrate multiple facets of thebusiness or enterprise, including planning, manufacturing, sales, andmarketing activities. Such an ERP client 104 may use a hub architectureand include capabilities for mapping and transforming data associatedwith these activities.

The CRM client 105 may be configured to manage multiple aspects ofinteraction between the organization/entity and its customers using avariety of electronic-based tools, including help-desk software, sales,marketing, e-mail organizers and Web development applications. Such aCRM client 104 may use a hub architecture and include capabilities formapping and transforming data associated therewith.

The additional enterprise clients, including the ETL client 102, EAIclient 103, ERP client 104, and CRM client 105, may each includevendor-specific application quality checking processes that operateinternally to each of the respective server applications. In at leastone embodiment, the enterprise business process server 101 may include aTransmission Control Protocol/Internet Protocol (TCP/IP) interface forexchange of information with additional enterprise servers including theETL client 102, EAI client 103, ERP client 104, and CRM client 105.Information exchanged between the enterprise business process server 101and the additional clients may include commands or requests from theenterprise business process server 101 to perform one or more particularprocesses or functions of a process (or processes) such as, for example,processes to check data quality. The exchanged information may alsoinclude data output by application quality checking processes orfunctions. The TCP/IP communication interface may allow the enterprisebusiness process server 101 to connect directly to any application onthe enterprise network. Alternatively, the TCP/IP communicationinterface may allow the enterprise business process server to connect toexternal applications using, for example, the Internet.

In at least one embodiment, the enterprise business process server 101may obtain information from the information data store 106 and the flatfiles data store 107. In particular, the enterprise business processserver 101 may include application instructions such as data storescripts for accessing, storing, or selectively retrieving informationcontained in the information data store 106 and the flat files datastore 107. The data store scripts may be implemented in the form ofprogramming statements provided in accordance with, for example, SQLversion 7.0 data store management system query language, as well asTransact® SQL (in accordance with the ColdFusion® data store managementsystem). Other data store implementations are possible, including, butnot limited to, those available from Oracles® or IBM DB2®.

In an alternative embodiment, the enterprise business process managementsystem 100 may include an enterprise database server (not shown) coupledto the enterprise business process server 101 and the information datastore 106 and the flat files data store 107 for the purpose of accessinginformation stored therein. The information data store 106 may includeenterprise application or transactional data arranged in accordance witha hierarchical data store management system format such as, for example,SQL. The flat files data store 107 may include enterprise application ortransactional non-hierarchical data.

The enterprise business process server 101 may also be coupled to one ormore mainframes 108 in the enterprise. The mainframe(s) 108 may includeorganization or enterprise applications such as, for example, legacypayroll or accounting systems. In at least one embodiment, theenterprise business process server 101 may communicate with themainframe(s) 108 using a Local Area Network (LAN), a Wide Area Network(WAN), dedicated landlines, or a combination thereof, among others.

Furthermore, in at least one embodiment the enterprise business processserver 101 may also be coupled to one or more terminals such as a callcenter terminal(s) 110, data entry terminals 111, local user terminal(s)112, and remote user terminal(s) 113 via LAN, WAN, dedicated landlines,an intranet, the Internet, a wireless network, or a combination thereof.The enterprise business process server 101 may thereby receivetransactional data from one or more of the terminals 110-113.

In addition, the enterprise business process server 101 may communicatewith users at one or more remote terminals 113 using, for example, theInternet 109. In at least one embodiment, the enterprise businessprocess server 101 may further include a web browser or thin client forthis purpose. The web browser displays data and is capable ofcommunicating with other computers via a network such as, for example,the Internet or an intranet. The web browser may provide a user with away to navigate, via, for example, hyperlinks which are selected by apointing device (such as a computer mouse) or typed in by the user. Theweb browser may use a protocol such as, for example, HyperText TransferProtocol (HTTP) or File Transfer Protocol (FTP), to transmit data ofvarious content such as, for example, HTML formatted documents, plaintext documents, graphic images, and XML documents for presentation to auser via a display.

FIG. 2 illustrates a computing platform that may be used to implementthe enterprise business process server 101 in accordance with at leastone embodiment of the invention. As shown in FIG. 2, the equipment 200may include a processor 210, a memory 220, a system interface 230, auser interface 240 and a communication/data/control bus 250 that coupleselements 210-240 together and allows for cooperation and communicationbetween those elements.

The memory 220 may be implemented utilizing alternative configurationsdepending on the needs of a user or a system associated with theenterprise business process management system. The system interface 230may include both hardware and software to allow the equipment 200 tocommunicate with components that provide data utilized by the enterprisebusiness process management system, for example, transactional datafeeds from the additional enterprise servers.

The processor 210 controls operation of the other elements 220-250,based on instructions fetched from the memory 220. The instructions mayinclude or be implemented as software code that dictates some or all ofthe operations of the enterprise business process management system 100and method explained herein. The memory 220 may include this code andmay also include storage area for data utilized by or generated by theenterprise business process management system 100. The processor 210 mayfetch the instructions, decode them, and act or instruct other elements120-150 to, for example, transfer data to or from the memory 220 or towork in combination with the system interface 230 or the user interface240 (for example, to input or output information), etc.

The processor 210 may actually be implemented as more than oneprocessor. The processor 210 may, based on instructions fetched from thememory 220, operate to control operation of the other elements 220-250.It should be appreciated that control may be implemented with theprocessor 210, for example, in a central processing unit, or othersimilar device. Similarly, the processor 210 and the memory 220 may beimplemented via one or more servers coupled to a network that allows theuser interface 240 to be implemented at a user terminal, such as localterminal 112 and remote terminal 113, and include a Graphical UserInterface (GUI) on a terminal screen.

The user interface 240 may include, for example, hardware and softwarefor cooperating with a terminal display, a keyboard and mouse, printer,etc. Moreover, the user interface 240 may include a speaker andmicrophone, not shown, for outputting and inputting information to andfrom a user. The user interface 240 may operate in conjunction with theprocessor 210 to allow a user to interact with software programs storedin the memory 220 and used by the processor 210 so as to perform theoperations explained below.

The enterprise business process server 101 can be implemented, forexample, as portions of a suitably programmed general-purpose computer.The system may be implemented, for example, as physically distincthardware circuits within an ASIC. Thus, it should be appreciated thatthe particular form of the system 100 may differ from the embodiment(s)explained herein. For example, although the enterprise businessmanagement system 100 has been described as being implementable on ageneral-purpose computer, for example, a personal computer, it isforeseeable that the system may be implemented in a network environmentwhere the software implementing the system is stored on one or moreservers. In at least one embodiment, the enterprise business processserver 101 may allow a user (e.g., an administrative user) to add,modify, or delete business process processes or steps without takingdown the server 101. Furthermore, the enterprise business process server101 may be scalable in order to easily function within server array orcluster environments and for processing of large volumes of data. In atleast one embodiment, the enterprise business process server 101 mayinclude a Microsoft Windows™ NT enabled personal computing platform, forexample.

In at least one embodiment, the enterprise business process server 101may include one or more applications programs containing a series ofprogrammed instructions that cause the enterprise business processserver 101 to be configured to perform the business process operationsas described herein. In particular, in at least one embodiment, FIG. 3illustrates a functional block diagram of an enterprise data qualityapplication 300 of the enterprise business process server 101. Referringto FIG. 3, the enterprise data quality application 300 may include acore architecture 301, a set of predefined view tools 302, a developer'skit 303, and an interface module 304, which may be a business analystinterface. The core architecture 301 may include a series of programmedinstructions for obtaining application data or transactional data fromone or more data sources, analyzing the obtained data for errors,logging detected errors, and generating at least one error reportaccording to a particular requested view. The enterprise data qualityapplication 300 may include one or more functions designed to analyze aparticular type of application data, which may be obtained from one ormore data sources, for occurrences of one or more types of errorspresent in the application data. In addition, the enterprise dataquality application 300 may include instructions causing a request to betransmitted to one or more of the additional enterprise servers,including the ETL server 102, EAI server 103, ERP server 104, and CRMserver 105, requesting execution of a particular application's internalquality checking processes or a particular set of functions of one ormore of the application's internal processes. In at least oneembodiment, the enterprise business process server 101 may transmitcommands/requests (e.g., function calls or procedure calls/RemoteProcedure Calls (RPCs)) and receive responses from the associated servervia the TCP/IP interface. The core architecture 301 may include amulti-threaded management layer for automatically converting any legacyapplications that are not multi-threaded to multi-threaded capabilities.

In an embodiment, the business analyst module 304 may include a sequenceof programmed instructions to implement the interface module (e.g.,business analyst interface or BAI) described herein. These instructionsmay, upon execution by the enterprise business process management server101, cause the enterprise business process management server 101 toprovide an interactive means to facilitate user interaction with theenterprise business process management system 100. In particular, thebusiness analyst module 304 may include instructions operable to causeprocess steps to be represented graphically, for example, using adisplay, and indicative of a particular operation to be accomplished bythe enterprise business process server when executing one or moreprocess steps of a business process. As such, the business analystmodule 304 may be an overlay application to the developer's kit 303. Thebusiness analyst module 304 may also include instructions operable tocause the enterprise business process server 101 to retrieve, build andcompile from a data store such as, for example, the data store 106, asequence of instructions implementing the business process defined by auser interacting with the interface module.

In at least one embodiment, the enterprise business process system 100may output error information in the form of one or more error reports.Error reports may be presented in accordance with a variety of views.The predefined view tools 302 may include programming instructionsassociated with one or more error reports provided in accordance with apredefined set of views. For example, the predefined view tools mayprovide instructions that cause the enterprise business process server101 to output an error report including a numeric count of errors for adata source for a manager's view. Further exemplary views and reportsare described hereinbelow.

The developer's kit 303 may include an Application Programming Interface(API) useful for users of the enterprise business process system 100 ortheir designated third parties to create and use customized view toolsfor analyzing particular data, sources, error syndromes, or forproviding customized reports over and above the set of predefined viewtools 302. There is no limit on the number of views supported by theenterprise business process management system 100.

In at least one embodiment, the enterprise business process server 101may be implemented in accordance with a client-server architecture.Programmed instructions, including the enterprise data qualityapplication 300, may be implemented in portable source code such as, butnot limited to, generic Microsoft® C. The enterprise business processserver 101 may be implemented in accordance with an encapsulated serverdesign in order to support clusters and server arrays. Furthermore, theenterprise business process server 101 may be implemented in accordancewith a stateless architecture approach to allow use of third-partytechnology for load balancing and high availability, for purposes ofproviding reliability and scalability to handle huge volumes of data. Inaddition, the enterprise business process server 101 may utilize“sandbox technology” (i.e., use of a combination of processsynchronization and isolation techniques such as, for example, handlingeach session via a separate thread) to allow legacy technology that wasnot multi-threaded, or even thread-safe, to be quickly and reliablyadded to the real-time, parallel processing environment.

FIG. 4 is a functional block diagram illustrating one contemplatedrelationship among data sources/destinations, products, and processesaccording to at least one embodiment of the invention. As shown in FIG.4, the enterprise business process server 101 may receive enterpriseapplication or transaction data from and transmit to one or more datasources/destinations 305. In at least one embodiment, the enterprisebusiness process server 101 may provide corrected data followingdetection of an error to a data source/destination 305 (e.g., datasource/destinations 1 through K). Furthermore, the enterprise businessprocess server 101 may receive process input from one or more products315 (e.g., Products 1 through M). A product 315 may include a functionor set of functions. In at least one embodiment, a function may be aroutine in a library that returns a value or set of values. In addition,the enterprise business process server 101 may include or access one ormore processes 310 to perform, for example, the data quality assurancefunctions described herein (e.g., Processes 1 through N). In at leastone embodiment, the enterprise business process server 101 may providean individual error log 325 for each process 310. Results from eachprocess 310, including any error log 325 generated, may be stored andmaintained using a log data store 320 (which may be the data store 160described with respect to FIG. 5).

The enterprise business process management system 100 may include anarchitecture designed to utilize an unlimited number of differentvendors' products in a unique process for each application (data source)or data set within an application. In particular, the enterprisebusiness process management system 100 may provide a framework for aunique process that creates, executes, manages and reports on individualprocess steps in a business process that utilizes different vendors'products on various platforms and enables these products to be usedacross the entire enterprise. The enterprise business process managementsystem 100 may provide archiving or logging of the quality of the databeing processed at each step in a multi-vendor environment. Theenterprise business process management system 100 may allow formanaging, tracking and reporting on the use of multiple vendors'products in a unique process for any application (data source) or dataset within an application. The enterprise business process managementsystem 100 may provide for the utilization of the same functions fromthe same or multiple vendors with different settings in a process. Theenterprise business process management system 100 may provide differentviews on the performance of individuals, business units, or specialconstituencies within an organization and the enterprise in regard toparticular aspects of the business process such as, for example, dataquality. The enterprise business process management system 100 mayprovide for comparisons of the effectiveness of various functions andsettings from different vendors for the selection of the most effectivefunctions and settings to handle a specific enterprise issue, such as,for example, a data quality issue. The enterprise business processmanagement system 100 may provide for the fast implementation ofmulti-vendor applications, such as data quality tools and data qualityprocesses.

In particular, the enterprise business process server 101 may utilize avendor independent architecture that allows for business process toolsto be used either on their current computer platform or on the sameplatform that hosts the enterprise business process server 101. In atleast one embodiment, the enterprise business process management system100 provides for reuse of functions of multiple business applications insystem 100 defined business processes.

FIG. 5 illustrates equipment that may be used to implement a system inaccordance with at least one embodiment. In particular, the enterprisebusiness process system 100 may include not only the enterprise businessprocess server 101, but may also include a data store 160 and a viewengine 170. The data store 160 need not be a single data store but maycomprise several data stores together. For example, the data store 160may be, but is not limited to, an OLAP (On-Line Analytical ProcessingDatabase) or a Summary Database. The data store 160 may include, but isnot limited to, formatting instructions and rules used by the viewengine 170 to produce an error report according to one of several views400. For example, the view engine 170 may obtain from the data store 160a sequence of formatting instructions and apply the thus-obtainedinstructions in generating an error report according to the associatedview 400. In at least one embodiment, each view 400 may be associatedwith a particular set of formatting instructions. The formattinginstructions may be implemented in the form of HyperText Markup Language(HTML) or Extensible Markup Language (XML) instructions designed tocause the view engine 170 to render an interactive page containing therequested error report according to the desired view. The interactivepage may be, for example, a world wide web page, or a page capable ofdisplay at a terminal 112 or 113 using a web browser application.

As can be seen in FIG. 5, the enterprise business process managementsystem 100 may provide several different views 400, including, but notlimited to, an end user view, a developer view, a manager view, and anexecutive view. Exemplary views 400 are described in further detail withrespect to FIGS. 7-10 below.

The enterprise business process management system 100 may provide theability to create different views 400 of the results of each step in aprocess for different levels of an organization to permit themeasurement and management of the effectiveness of the organization'sbusiness processes. The enterprise business process management system100 may include visualization software that creates graphicalinformation for the different views 400. This graphical information mayinclude analytical tools, statistical information, data tracking, costanalysis and, in at least one embodiment, an indication of the impact ofthe results of the different levels of the organization in reducing theerrors in data quality.

In order to support the generation of error reports in accordance with avariety of views 400, the data store 160 (which may be an onlineapplication processing database or summary database) may maintain errorreport information in accordance with a “single view” in whichinformation contained in the data store 160 is formatted and arranged ina consistent manner equally accessible by the view engine 170 for theproduction of any view 400, regardless of the data source/destination305, product 315, or process 310 from which the data was obtained.

The enterprise business process management system 100 may log theresults of each step in a process from every data source. This log mayprovide information regarding who sent the data, what occurred duringeach step of the process, and where the data was sent after the processwas completed. This log may feed directly into the view engine 170,which may be a graphical reporting system, for rendering of multipleviews.

In at least one embodiment, view engine 170 may provide graphicalreports to various users including executives, managers, end users, andprocess developers that convey information regarding how they, theirdepartment, organization or processes are performing. In particular, inat least one embodiment, view engine 170 may provide the following views400, for example views for Executives, Managers, Users, and Developers.The Executive View provides graphical reports on the quality of data forthe whole organization. Executives can drill down into the performanceof every segment within the organization to compare performances andcauses of data quality issues. Executives have access to Manager andUser Reporting modules as well. The Managers View provides graphicalreports on the quality of data in the manager's organization(s) anddepartment(s). Managers can drill down into the performances of theirbusiness units and departments and compare performances and causes ofissues such as, for example, data quality. The Users View providesgraphical reports on the quality of the data that has been entered byusers into the system. Users can drill down on the specific problems andreview the input and output data and result codes of each step in theprocess. The Developers View provides graphical reports on the resultsof all processes and steps so that developers may analyze the resultsand make changes to the process to improve the results. Developers canreadjust the sequences of functions, eliminate functions, utilizefunctions from other vendors, add new functions from different vendorsand create new functions themselves.

The view engine 170 may include statistical modeling packages that canbe used to add the financial impact of data that is validated/correctedand not validated/corrected. In at least one embodiment, the view engine170 may be implemented using graphical modeling technology availablefrom, for example, Illumitek™ Corp. of Dulles, Va.

FIG. 6 provides further details concerning implementation of theanalysis that may be performed by the enterprise business processmanagement system 100. The enterprise data quality management system 100may provide for the creation of a unique process for each application ordata set from that application using all or a subset of the functionsand settings available within all the business process products presentin the enterprise network and externally available. Each application ordata set within an application is capable of utilizing all the functionsand settings in a sequence appropriate for meeting unique needs. Suchbusiness processes may be composed of an unlimited number of steps. Eachstep may correspond to a function and setting or a series of functionsand settings from a particular vendor. The enterprise business processmanagement system 100 may provide archiving and logging of the resultsof every step in a multi-vendor process. Log files may be automaticallylogged to a text file or a data store. In particular, errors may bedetermined and logged at the process level.

The enterprise business process management system 100 may include theability to compare the strengths and weaknesses of each vendor'sfunctions and settings in a multi-vendor, multi-step process.Furthermore, the enterprise business process management system 100 mayprovide a fast, easy to use methodology for installing products andfunctions from multiple vendors to expedite the implementation ofbusiness process projects. Thus, in at least one embodiment, theenterprise business process management system 100 may be vendorindependent while allowing users access to all the functions included inadditional enterprise servers or application, including existingbusiness process vendor products, custom codes, or services. Through useof the function oriented approach as described herein, a user maysequence the business process functions, such as, for example, dataquality functions, from different vendors in any order determined to fitthe needs of each data set and data source. Furthermore, a user mayestablish unique processes 310 and steps for each data set within a datasource as described with respect to FIG. 11.

A vendor may be a software company that provides functionality to, forexample, identify and separate into distinct fields the elements of abusiness and consumer name; identify, separate, validate and correcteach element of an address; identify, separate, validate, correct andtransform non-name and address information for on-line transactions andbatch processing; consolidate data from different records and differentdata sources; augment the original data with additional data; and createa single record or view of that individual or client.

The enterprise business process management system 100 may include aGraphical User Interface (GUI) capable of allowing a user to create aprocess for an application or data set from an application. The user mayspecify the format for the data, and may also create individual steps ina process by calling a specific function(s) and setting(s) from anavailable tool for each step. The GUI may be implemented using Java®instructions, for example. The user may repeat the exercise of creatingsteps until a business process is fully defined and completed. Theprocess may be represented, viewed and navigated in a hierarchicalfashion where a single step may represent a multi-step sub process. Theprocess depiction and description may be presented on other outputdevices, such as printer. The process depiction and description may beexported for viewing and manipulation by external applications, such asa word processor, flow chart application, or web browser. The user maythen identify the destination(s) for the results of the process anddecide what information is to be sent to each destination. The resultsof each step within a Process may be logged to a text file or datastore. The data that is stored in the text file or data store may usedby a view engine, which may include visualization software, to creategraphical reports, which contains analytical information, statisticalinformation, data tracking, cost analysis, and the impact of data forthe different levels within an organization. This information may beused to measure and monitor the effectiveness of an enterprise businessprocess such as, for example, a data quality program.

FIG. 39 shows the relationship between the interface module 304,enterprise business process server 101, and router 3905 in anembodiment. Referring to FIG. 39, input data 605 from a data source suchas, for example, a business application, may be received by theenterprise business process server 101. In an embodiment, the input data605 may include a process identifier specifying a particular businessprocess to which the input data 605 is to be applied. The enterprisebusiness process server 101 may be configured to detect the input data605 process identifier and provide the input data 605 to the specifiedbusiness process of the router 3905. In an embodiment, the router 3905may include an integrated instruction set embodying one or more businessprocesses (e.g., processes 1, 2 and 3 are shown in FIG. 39). Theinstructions for each business process may include calls to tools 3910(i.e., functions) residing external to the router 3905 for performingprocess steps, as well as tools 3910 obtained from business applicationsexternal to the router 3905 but residing on the router 3905.

In at least one embodiment, the router 3905 may be an interchangeablerouter in which new versions or loads for the router 3905 may replacethe current router 3905 version, and be placed in service and handledata traffic, without the need to take the server 101 down (i.e, out ofservice). The router 3905 may include the instruction set for thecurrently active business processes provided by the enterprise businessprocess management system 100. A new router 3905 version may be builtand placed into service to begin data traffic handling according to anew or modified business process. In an embodiment, the interface module304 may generate an instruction set embodying a new or modified businessprocess in response to user entered function information. The user mayenter the function information using, for example, a process designerinteractive page provided by the interface module 304. Followingreplacement of the current router version with a new router version,input data 605 may be handled according to the new router version.Further details concerning the replacement of a current router versionwith a new router version are described with respect to FIGS. 23 a-dherein.

Referring to FIG. 6, a method 600 may commence with the enterprisebusiness process server 101 receiving input data at 605. The input data605 may be received from a data source/destination 305.

Control may then proceed to 610 at which the input data may be passed toa process router. Based on a process identifier, the process router maydirect the input data to a particular process 310 (e.g., Process X). Inat least one embodiment, the process router may allow processes andsteps to be easily and quickly modified without bringing down the server101 (i.e., an interchangeable or hot swappable router).

Control may then proceed to 615, at which the process 310 (e.g., ProcessX) may receive the input data and pass it to each step in a multiplestep process. An example of a business process is a data quality processsuch as an address validation operation in which transactional data(obtained from a data source/destination 305 associated with aparticular enterprise application) is compared to a trusted source suchas, for example, a United States Postal Service database. Control maythen proceed to a second step at 620 and thereafter to subsequent steps(e.g., Step N) at 635. After each step in the process 310, the resultsof the step may be entered into a log 630, such as, for example, errorlog 315, and the data is passed to the next step. The results of eachstep of the process 310 and the error log 315 may be maintained in adata store 625, such as the data store 160. As mentioned above, the datastore 625 (and the data store 160) may be, but is not limited to, anOLAP (On-Line Analytical Processing Database) or a Summary Database.Logging may include server Logging (e.g., logging of all transactionsreceived by the server, logging of server statistics) as well as processlogging (e.g., detailed logging of each step within a process that canbe used for analysis on transaction data and product abilities).

After the final step in the process 310 has been completed, control mayproceed to 640 at which the process results may be applied to an outputdata structure. The output data may then be provided to a datasource/destination 305, following which processing may end for themethod 600.

In at least one embodiment, a process 310 may include fields such as,but not limited to, ROME_ID, ROME_TIME, SECT_CODE, SOURCE_DEST,SUB_SOURCE_DEST, RETURN_CODE, and INPUT COMPONENT 1-N. Each step in aprocess 310 may include fields such as, but not limited to, ROME_UID,ROME_TIME, PRODUCT_ID, PRODUCT_RC, STEP_ID, and OUTPUT COMPONENT 1-M.Each data packet may have a unique identifier (e.g., “ROME_ID”) that canbe used to track the results of multiple submissions of the same datapacket.

As described earlier herein with respect to FIG. 5, for example, in atleast one embodiment, the enterprise business process server 101 mayprovide error reports in accordance with one or more views 400. FIG. 7is an example of an error report for an executive view according to atleast one embodiment of the invention. As shown in FIG. 7, an executiveview 700 may include one or more error reports providing data errorinformation for a variety of divisions 705 of an enterprise. Forexample, the exemplary executive view 700 shown in FIG. 7 may present anerror report for divisions 705 including marketing, finance, sales,development, web, and customer support divisions, giving the requestinguser (e.g., enterprise executive) visibility into aspects of theenterprise such as, for example, data quality, so that corrective actionmay be taken, for example. In at least one embodiment, incorrect orerrored records may be marked to indicate that they were not corrected,and the reasons for such.

In particular, an error report may provide in numeric as well asgraphical form, using tools such as charts 715 and 720, ranking orstatistical analysis of the errors detected in a given set of enterpriseapplication data or transactional data. For example, in at least oneembodiment the enterprise business process management system 100 mayperform analysis processes that provide information to the requestinguser such as, but not limited to, a ranking of the data errors 720detected for applications within different divisions 705, a trafficintensity indicator 710 for data transactions flowing into and out of adivision 705, a productivity chart 715 showing the change inproductivity for each division 705 over time, and a process errorclassification 725 of the strengths, weaknesses, costs, and gainsassociated with the data quality for the divisions 705.

Similarly, FIGS. 8-10 are examples of an error report for a customersupport view 800, an individual view 900, and a manager view 1000,respectively, according to at least one embodiment. Items includingreference numbers identical to those appearing in FIG. 7 are asdescribed earlier with respect thereto.

In particular, for individual view 900, the enterprise business processmanagement system 100 may provide visibility to the requesting userinto, for example, data errors attributable to a particular individual.For example, FIG. 9 shows a process error classification 725 of thestrengths, weaknesses, costs, and gains associated with a particularindividual 905, as well as the error types 910 committed by theindividual 905 and the number of errors distributed over time 915attributable to the individual 905. The example error classification 725of the error report in FIG. 9 shows that the individual 905 is strong(i.e., few errors committed) in entering address information, is weak(i.e., many errors) in entering names, has committed 80, 74, and 22errors in different time periods, and has cost the enterprise $800 as aresult of the data errors.

Furthermore, for manager view 1000, the enterprise business processmanagement system 100 may provide visibility to the requesting user(e.g., enterprise manager) into data errors attributable to particularindividuals 905 and to the individuals as a group. For example, FIG. 10shows a process error classification 725 of the strengths, weaknesses,costs, and gains associated with multiple individuals 905, as well asthe error types 910 committed by each of the individuals 905 and thenumber of errors distributed over time 915 (e.g., time of day)attributable to the group. A cost per time period chart 1005 may also beprovided indicating the daily cost incurred by the enterprise for thedata errors attributed to each individual 905.

In at least one embodiment, the enterprise business process managementsystem 100 may provide the capability for a user (e.g., anadministrative user) to create and establish business processes 310 forexecution by the enterprise business process server 101. FIG. 11 is aflow chart of a method 1100 of establishing an exemplary data qualityprocess for the enterprise business process management system 100 inaccordance with at least one embodiment. The method 1100 may commence at1105 upon the enterprise business process server 101 receiving a userrequest to create a process 310. A user may enter a request to create aprocess 310 by, for example, using a pointing device to select anassociated hyperlink contained on an interactive page provided by agraphical user interface portion of the enterprise data qualityapplication 300.

Control may then proceed to 1110, at which the enterprise businessprocess server 101 may prompt the user to create a process name andselect a data source for the process 310. FIG. 12 is an example of aninteractive page 1200 provided by the enterprise business process server101 in which a user may enter a process name, description, andassociated data source 305.

Control may then proceed to 1115, at which the enterprise businessprocess server 101 may prompt the user to enter a new data source 305,if necessary. If the user responds by requesting to add a new datasource 305, control may proceed to 1120 at which the enterprise businessprocess server 101 may generate and output an interactive page 1300 fora user to add a data source 305. FIG. 13 is an example of an interactivepage 1300 provided by the enterprise business process server 101 inwhich a user may add a data source 305 by entering information such as,but not limited to, a data source name, description, IP address, PortNumber, and platform identifier.

Control may then proceed to 1125, at which the enterprise businessprocess server 101 may prompt the user to create an input packet for theprocess 310. FIG. 14 is an example of an interactive page 1400 providedby the enterprise business process server 101 in which a user may createan input packet by entering attribute information such as, but notlimited to, an input element name, type, length, and description. Theinput element type may specify a data type for the input packet such as,but not limited to, boolean, character, double character, wide character(UNICODE), floating point decimal, integer, long integer, or shortinteger.

Control may then proceed to 1130, at which the enterprise businessprocess server 101 may prompt the user to create an output packet forthe process 310. FIG. 15 is an example of an interactive page 1500provided by the enterprise business process server 101 in which a usermay create an output packet by entering attribute information such as,but not limited to, an output element name, type, length, anddescription. The output element type may specify a data type for theoutput packet such as, but not limited to, boolean, character, doublecharacter, wide character (UNICODE), floating point decimal, integer,long integer, or short integer.

Control may then proceed to 1135, at which the enterprise businessprocess server 101 may prompt the user to select a product 315 (orfunction or set of functions, as the case may be) to be associated withthe process 310. A product 315 may include a function or a set offunctions. FIG. 16 is an example of an interactive page 1600 provided bythe enterprise business process server 101 using which a user may selecta product 315 by entering, as a minimum, a selection of a product 315from a pull-down list, for example, and a product description.

Control may then proceed to 1140, at which the enterprise businessprocess server 101 may prompt the user to add a product 315, ifnecessary. If the user responds by requesting to add a product 315,control may proceed to 1145 at which the enterprise business processserver 101 may generate and output an interactive page 1700 for a userto add a product 315. FIG. 17 is an example of an interactive page 1700provided by the enterprise business process server 101 in which a usermay add a product 315 by entering information such as, but not limitedto, a product name, product type, version, and product template.APPENDIX A hereto provides an exemplary sequence of pseudocodeinstructions for creating a product template.

Control may then proceed to 1150, at which the enterprise businessprocess server 101 may prompt the user to select a data destination 305for the process 310. FIG. 18 is an example of an interactive page 1800provided by the enterprise business process server 101 in which a usermay enter a data destination name and description.

Control may then proceed to 1155, at which the enterprise businessprocess server 101 may prompt the user to enter a new data destination305, if necessary. If the user responds by requesting to add a new datadestination 305, control may proceed to 1160 at which the enterprisebusiness process server 101 may generate and output an interactive page(not shown) for a user to add a data destination 305 by enteringinformation such as, but not limited to, a data destination name, IPaddress, Port Number, and description. In at least one embodiment, allor a portion of data output by the enterprise business process server101 may go to one or more data destinations 305.

Control may then proceed to 1165, at which the enterprise businessprocess server 101 may prompt the user to establish the process 310.FIG. 19 is an example of an interactive page 1900 provided by theenterprise business process server 101 in which a user may review andconfirm information associated with the process 310 as described above.Summary process information provided by the page 1900 may include, butis not limited to, the process name, its data source 305, the input andoutput data specifications, the associated product 315 list, and thedata destination(s) 305 for the process output. After a process 310 hasbeen created, it may be edited (i.e., source code edit). Edited processinstructions may be compiled into the process router. In at least oneembodiment, the instructions may be source code instructions.

Processing for the method 1100 may end at 1170.

It should be noted that the data output from the system and methoddescribed may be provided in whole or in part to one or moredestinations 305. In other words, all of the output data may be directedto a single destination 305. Alternatively, portions of the output datamay be sent to multiple destinations 305.

FIG. 24 provides a functional block diagram showing the relationshipamong fictions, processes and products (e.g., tools) involved in thedefinition of data quality business processes in an embodiment.

In at least one embodiment, the enterprise business process managementsystem 100 may include an interface module, an example of which isdescribed more particularly below. The interface module may also includeaspects of the user interface described earlier herein. In anembodiment, the interface module 304 may be implemented as component ofthe enterprise data quality application 300 as shown in FIG. 3. Theinterface module may provide the capability for a user to define,create, modify, test and execute a sequence of function steps for abusiness process using the enterprise business process management system100. In particular, the interface module may include an interactivegraphically-oriented process specification tool that allows a user todefine or modify a business process by, for example, selecting andmoving (e.g., dragging and dropping) symbols relating to processfunctions to a display location representing a particular process step.Each process step may be represented, for example, as one or morefunction icons grouped together as shown generally in FIG. 20. FIG. 20shows an example process designer interface interactive display 2000provided in accordance with at least one embodiment. Thus, the interfacemodule process designer may be used to define or specify a businessprocess to be performed by the enterprise business process managementsystem 100. As an overlay application to the developer's toolkit 303,the interface module 304 may provide interactive pages similar or inaddition to FIGS. 12-19 described earlier herein.

A function may be a named section of a program that performs a specifictask. In this sense, a function may be a type of procedure or routine.Some programming languages make a distinction between a function, whichreturns a value, and a procedure, which performs some operation but doesnot return a value. Most programming languages come with a prewrittenset of functions that are kept in a library. Custom functions may alsobe developed that perform specialized tasks. For example, in the Clanguage and certain other programming languages, a function is a namedprocedure that performs a distinct service. The language statement thatrequests the function is called a function call.

Referring to FIG. 20, the process designer interactive display 2000 mayinclude a function library 2005, a process input area 2010, a processstep definition area 2015, and a process output area 2020. Each processstep 2025 may be represented, for example, as one or a group of functioninputs 2030, function outputs 2040, and function identifiers 2035 withinthe process step definition area 2015. Each function input 2030 may be(or may not be) linked to an input element 2075 within the process inputarea 2010 using, for example, a link 2045. A link 2045 is also referredto as a connection or “road.” Similarly, the each function output 2040may be (or may not be) linked to an output element 2080 within theprocess output area 2020 using, for example, a link 2045. In anembodiment, links 2045 may be used to represent the directional flow ofinformation from source to destination such as, for example, from aninput element 2075 to a function input 2030. The flow of information maybe controlled by at least one router that uses packet header informationand a routing table to determine the destination or target. Furthermore,process steps 2025 may be linked to form, for example, a chain ofsuccessive process steps 2025 to be sequentially accomplished in abusiness process.

FIG. 25 shows an example of a functions overview interactive pageprovided in an embodiment. Referring to FIG. 25, a functions overviewpage 2500 may provide a listing of all functions currently included inthe function library 2005. Functions therein may be ordered according toa variety of criteria such as, for example, chronologically by order ofcreation.

FIG. 26 shows an example of a process definition area portion of aprocess designer interactive page 2000 provided in an embodiment.

Each process step 2025 may represent a particular operation to beaccomplished by the enterprise business process server when executingthat process step 2025. In particular, a process step 2025 may includeone or more function inputs 2030 and function outputs 2040. Furthermore,a function identifier 2035 may represent a particular operation to beperformed using the function input(s) 2030 to produce the functionoutput(s) 2040. In an embodiment, the enterprise business processmanagement system 100 may perform many different process steps 2025obtained from multiple application providers within a single businessprocess. In at least one embodiment, the function identifier 2035 mayserve to specify the functions and function elements of a particularapplication provider whose application(s) is used by the enterprise.Furthermore, multiple business processes may be supported by theenterprise business process management system 100.

In at least one embodiment, a user of the enterprise business processmanagement system 100 may interact with the process designer interactivedisplay 2000 to create and modify process steps 2025 which make up abusiness process. In particular, the user may manipulate, move and linkthe display icons or symbols representing function inputs 2030, functionoutputs 2040, function identifiers 2035, input elements 2075, outputelements 2080 and links 2045 using, for example, a pointing device ofterminals 110-113. Alternatively, a keyboard device may be used for thispurpose. For example, a new function input 2030 may be added to aprocess step 2025 by dragging and dropping (e.g., selecting) the newfunction input 2030 from the function library 2005 to the desiredprocess step 2025 of the process step definition area 2015. FIG. 27shows an example interactive page of the process designer 2000illustrating adding an element of a process step 2025 from the functionlibrary 2005 in an embodiment. If the new function input 2030 requiresan input element 2075, then the user may, for example, drag and drop thedesired input element 2075 from the function library 2005 to the inputarea 2010 and add a link 2045 from the new input element 2075 to the newfunction input 2030. FIG. 28 shows an example interactive page of theprocess designer 2000 illustrating linking of process steps 2025 in theprocess definition area of a process designer interactive page in anembodiment.

In an embodiment, a function input 2030 may include a conditionalstatement to specify alternative actions to be taken upon the occurrence(or not) of a specified event. FIG. 29 shows an example interactive pageportion 2900 by which a conditional statement may be defined for anelement of a process step according to at least one embodiment.

FIG. 30 shows an example of a products definition interactive page 3000provided in an embodiment similar to FIG. 17. FIG. 31 shows an exampleof a data destination definition interactive page 3100 provided in anembodiment similar to FIG. 18. FIG. 32 shows an example of a productsselection interactive page 3200 provided in an embodiment similar toFIG. 16.

In at least one embodiment, the enterprise business process managementsystem 100 may retrieve, build and compile from a data store such as,for example, the data store 106, a sequence of instructions implementingthe business process defined by the interface module process designer.In an embodiment, the interface module 304 of the enterprise businessprocess server 101 may obtain a sequence of instructions implementingone or more business processes defined using, for example, the interfacemodule, from the data store 106 for execution by the enterprise businessprocess server 101.

In at least one embodiment, the interface module 304 may assemble (i.e.,build) a sequence of instructions implementing the interface moduleprocess designer defined process steps 2025 in a series of build stepsutilizing a number of build files. FIG. 21 shows a series of build filesutilized in an embodiment by the enterprise business process server tobuild a code implementation of a business process. Referring to FIG. 21,a set of build files for a business process may, in an embodiment,include at least one temporary step build file(s) 2050, a process stepsfile 2055, one or more function attributes file(s) 2060, one or moreassociated function temporary files(s) 2065, and a process file 2070.The enterprise business process management system 100 may use thesefiles in an embodiment to implement a business process defined by abusiness analyst, for example, using the interface module processdesigner in the following manner.

In an embodiment, all functions that have been added to the enterprisebusiness process management system may appear in the function library2005 (FIG. 20). Each function may be identified in the function library2005 by a function name and an icon, for example. The functionattributes file 2060 may contain all of the necessary information, inXML format, for example, so that when this function is added as a stepin a process the function will be displayed on the interface moduleprocess designer 2000 with the correct number of function inputs 2030,function outputs 2040, and will have the associated settings defined bythe content parameters of data fields used by or produced by thefunction. In an embodiment, every function in the enterprise businessprocess management system 100 has its own function attributes file 2060.Function step 2025 shows an example of a function as is appears usingthe interface module process designer 2000 when added as a step to abusiness process. When a function is added to the business process, theinterface module 304 first reads the function attributes file 2060 forthat function. After reading the function attributes file 2060, theinterface module 304 builds the necessary input and output elements forthat function as they are defined in the function attributes file 2060.

In an embodiment, the interface module 304 may include a function wizardthat provides a sequence of interactive pages to the user operable toassist the user in importing a pre-built function into the library ormodifying an existing function. The function wizard may includeinteractive fields of one or more interactive pages in which a user mayenter a function name, choose a function icon, enter an associatedproduct name, enter a function type, and add a function description. Thefunction wizard may provide a function template in response to the userentered information. Function templates may be maintained using, forexample, the function template files 2065. The function template mayinclude a sequence of instructions that define various aspects of thefunction (e.g., variables). The actual values for each function variablemay be determined by a function setting that corresponds to eachfunction variable. FIG. 33 shows an example of the content of a functiontemplate file page 3300 provided in an embodiment.

After the function has been added to the business process, a temporarystep file 2050 may be created. In an embodiment, the temporary step file2050 may be provided in XML format. The temporary step file 2050 maycontain all of the information about the function as it pertains to thisstep in the business process. It is important to note that the temporarysteps file may be different for every step, even if it is from the samefunction.

Furthermore, as illustrated in FIG. 21, the interface module 304 maycreate the process steps file 2055 when the business process is to bebuilt. In an embodiment, the process steps file 2055 may be the joinedgroup of temporary step file(s) 2050 associated with this businessprocess.

Finally, the interface module 304 may create the process instruction setfile 2070 as follows. First, the interface module 304 may read theprocess steps file 2055. Since each step in may correspond to a functionin the function library, the interface module may retrieve the functionattributes file 2060 for each step in the process steps file 2055, andthen map the data in the process steps file 2055 to the correspondingfields in the function attributes file 2060. Next, after the informationfrom the process steps file 2055 has been linked to corresponding fieldsin the function attributes file 2055, the interface module 304 may thenmap each function attributes file 2060 to a function template file 2065.The function template file 2065 may, in an embodiment, contain sourcecode instructions (e.g., ‘C’ source code) to be added to the sequence ofinstructions implementing the process. Furthermore, in at least oneembodiment, the function template file 2065 may include XML tags thatcorrespond to fields in the associated function attributes file 2060. Asthe function template file source code is being added to the source codein the process instruction set file 2070, the interface module 304 mayreplace the XML tags in the function template file 2065 with the datathat was provided in the function attributes file 2060 which was in turnthe data that was provided from the process steps file 2055.

In an embodiment, following build of a new process instruction set file2070, the enterprise data quality application 300 may build a new routerDLL including the new process source code file 2070 as shown in FIG. 22.In at least one embodiment, the instruction set file 2070 may includesource code instructions. Referring to FIG. 22, the enterprise dataquality application 300 may build a new router DLL 2071 including thenew process instruction set file 2070 (e.g, Process File 1) along withother process instruction set files (e.g., Process Files 2-K). The newrouter DLL 2071 may then be loaded by the enterprise business processserver 101 and placed into service, at which point the new process maybe executed.

FIGS. 23 a-d provide a flow chart illustrating more particularly amethod of implementing a business process in accordance with at leastone embodiment. Referring to FIG. 23, a method may commence at 2300 andproceed to 2302. At 2302, a user may send a request to the enterprisebusiness process server 101 to create or modify a business process. Inan embodiment, the user request may be output by the terminal 110, 111,112 or 113 to the enterprise business process server 101 using a networksuch as, for example, a packet-based network. An example of apacket-based network is the Internet. The user may be a businessanalyst, for example. In an embodiment, the request may be provided asan XML-formatted request. In response, the enterprise business processserver 101 may output to the requesting terminal 110, 111, 112 or 113 aninteractive page such as, for example, the interface module processdesigner interactive display 2000. In an embodiment, the interfacemodule process designer interactive display 2000 may be provided in theform of an XML-formatted interactive page suitable for display at theterminal using a web browser application of the terminal.

Control may then proceed to 2304, at which the user may desire to add aprocess step to or modify a process step of the business process(reference FIG. 20). Control may then proceed to 2306, at which the usermay determine that a function to be added to a process step, or forwhich a new process step is to be added, may need to be added to thefunction library. If so control may proceed to 2308. If not, control mayproceed to 2312.

At 2308, the user may enter information defining a new function into thefunction library. Such information may include, but is not limited to, afunction name and a function icon. The function name may provide a briefdescription of the operation provided by the function. The function iconmay be a symbol representing the vendor or provider of the applicationfrom which the function is taken. In an embodiment, all functions usedin process steps must be included in the function library.

Control may then proceed to 2310, at which the user may defineparticular function attributes using the function attributes file. Thefunction attributes file may include all information necessary to definea function information, in XML format, so that when this function isadded as a step in a business process the function will be displayed onthe interface module process designer with the correct number offunction inputs and function outputs, as well as its associated functionsettings. In an embodiment, the function attributes file may be providedin accordance with the XML format. Also in an embodiment, every functionin the function library may have an corresponding function attributesfile. FIG. 34 shows an example of a function settings interactive page3400 provided in an embodiment.

Control may then proceed to 2312, at which a temporary step file may becreated as follows. When a function is added to the business process,the interface module may first read the function attributes file forthat function. After reading the function attributes file, the interfacemodule may build the necessary input and output elements for thatfunction as they are defined in the function attributes file. In anembodiment, the temporary step file may be provided in XML format. Thetemporary step file may contain all of the information about thefunction as it pertains to this step in the business process. It isimportant to note that the temporary steps file may be different forevery step, even if it is from the same function.

Control may then proceed to 2314, at which the interface module maycreate the process steps file. In an embodiment, the process steps filemay be the joined or assembled group of temporary step file(s)associated with this business process.

Control may then proceed to 2316, at which the interface module mayretrieve the function attributes file for each step in the process stepsfile. Control may then proceed to 2318, at which the interface modulemay map the data in the process steps file to the corresponding fieldsin the function attributes file. Control may then proceed to 2320, atwhich the interface module may map each function attributes file to afunction template file. The function template file may, in anembodiment, contain source code instructions (e.g., ‘C’ source code) tobe added to the sequence of instructions implementing the process.Furthermore, in at least one embodiment, the function template file mayinclude XML tags that correspond to fields in the associated functionattributes file.

Control may then proceed to 2322, at which the interface module mayreplace the XML tags in the function template file with the data thatwas provided in the function attributes file, which was in turn the datathat was provided from the process steps file.

Control may then proceed to 2324, at which the interface module mayassemble the data-populated function template files into a processinstruction set file containing a sequence of program instructionsimplementing the process. Control may then proceed to 2326, at which theinterface module may store the process instruction set file in a datastore. The instruction set file may be, but is not limited to, a sourcecode file.

Control may then proceed to 2328, at which the enterprise data qualityapplication core application may determine if the user has specified thebusiness process to be a test process or a production process. In anembodiment, the business analyst module 304 may provide an interactivepage (not shown) for the user to specify whether a test build or aproduction build of the router is to be performed. If a test process,control may proceed to 2330 at FIG. 23 c. If a production process,control may proceed to 2350 at FIG. 23 d.

At 2330 of FIG. 23 c, at which following the build of a new test processinstruction set file, the enterprise data quality application coreapplication may build a new router DLL including the new test processinstruction set file (see FIG. 22). The test process instruction set maybe optimized for production.

Control may then proceed to 2332, at which the interface module maynotify the enterprise business process server that a new router is readyto be loaded. Control may then proceed to 2334, at which the enterprisebusiness process server may pause and halt any transactions fromentering the current router, allow all transactions currently in therouter to finish processing, and unload the current router.

Control may then proceed to 2336, at which the enterprise businessprocess server may notify the interface module that the current routerhas been unloaded.

Control may then proceed to 2338, at which, upon receiving notificationthat the current router has been unloaded, the interface module mayarchive the current (i.e., “old”) router, replace it with the newlybuilt router, and notify the enterprise business process server to loadthe new router.

Control may then proceed to 2340, at which the enterprise businessprocess server may load and initialize the new router and allowtransactions to enter the new router.

Control may then proceed to 2342, at which the enterprise businessprocess server may notify the interface module that the new router hasbeen loaded.

Control may then proceed to 2344, at which, upon receiving notificationthat the new router has been loaded, the interface module may output tothe terminal of the user a process tester interactive page. FIG. 35shows an example process tester interactive page 3500 according to anembodiment. A process tester interactive page 3500 may include a processtest steps listing 3505.

Control may then proceed to 2346, at which the terminal may output theprocess tester interactive page to the user via, for example, a displayof a web browser application. FIG. 36 shows an illustration of adata-populated process definition area of a process tester interactivepage 3500 in an embodiment in which the interface module has replacedthe XML tags in the function template file with the data that wasprovided in the function attributes file.

Control may then proceed to 2348, at which a method may end.

At 2350 of FIG. 23 d, at which following the build of a new productionprocess instruction set file, the enterprise data quality applicationcore application may build a new router DLL including the new productionprocess instruction set file (see FIG. 22). The production processinstruction set may be optimized for production.

Control may then proceed to 2352, at which the interface module maynotify the enterprise business process server that a new router is readyto be loaded. Control may then proceed to 2354, at which the enterprisebusiness process server may pause and halt any transactions fromentering the current router, allow all transactions currently in therouter to finish processing, and unload the current router.

Control may then proceed to 2356, at which the enterprise businessprocess server may notify the interface module that the current routerhas been unloaded.

Control may then proceed to 2358, at which, upon receiving notificationthat the current router has been unloaded, the interface module mayarchive the current (i.e., “old”) router, replace it with the newlybuilt router, and notify the enterprise business process server to loadthe new router.

Control may then proceed to 2360, at which the enterprise businessprocess server may load and initialize the new router and allowtransactions to enter the new router.

Control may then proceed to 2362, at which the enterprise businessprocess server may notify the interface module that the current routerhas been unloaded.

Control may then proceed to 2364, at which, upon receiving notificationthat the new router has been loaded, the interface module may output tothe terminal of the user a main processes interactive page.

Control may then proceed to 2366, at which the terminal may output themain processes interactive page to the user via, for example, a displayof a web browser application.

Control may then proceed to 2368, at which a method may end.

In at least one embodiment, the enterprise business process server 101may retrieve and execute a particular business process upon receiving apacket of input elements associated with that business process from adata source via a connection. In at least one embodiment, such aconnection may be a compiled dynamic link library (DLL) file that mapsthe business application function input data and output data tocorresponding information fields of functions of an associated businessprocess. FIG. 37 shows an example of a connection definition interactivepage 3700 by which a user may define a connection according to at leastone embodiment. Each enterprise application may have a correspondingconnection maintained using the data store 106, for example, that mapsits functions to one or more business processes executed by theenterprise business process server 101. Upon receiving an associatedpacket of input elements, the enterprise business process server 101 mayretrieve and execute the associated business process and produce itsresultant output elements. In an embodiment, the enterprise businessprocess server 101 may send a packet containing the output elements to adata destination via the connection for further processing. A connectionmay encapsulate data routing information specifying the path between toenterprise nodes. In an embodiment, the connection may be a socketconnection for a packet-based network such as, for example, TCP/IP.

Thus, an interface module may provide the capability for a user, such asa business analyst for example, to define, create, modify, implement,test and execute a business process using the enterprise businessprocess management system without having to undertake a lengthyrequirements definition, general design, detailed design, coding andtesting cycle involving software engineering or programming personnel.The interface module of the enterprise business process managementsystem as shown herein allows rapid iterative development andimplementation of business processes, reducing development costs andtime, as well as reducing the need to periodically freeze functionalrequirements.

Thus, an enterprise business process management system has beendescribed, embodiments of which may provide an integrated data qualitymanagement system capable of collecting, analyzing, and reportinginformation concerning qualitative and quantitative aspects ofapplication or transactional data throughout an enterprise. It should beunderstood that the enterprise data quality management system describedherein is but one aspect of the enterprise business process managementsystem of the present invention. One skilled in the art would be capableof determining other embodiments of the present invention based on thedisclosure herein. In particular, the enterprise business process server101 may be more generally described as a server capable of providing oroperating in conjunction with many different enterprise business processapplications. In general, such an enterprise business process managementsystem may provide the capability to collect, analyze, and reportinformation concerning qualitative and quantitative aspects ofapplication or transactional data throughout an enterprise across someor all of the computing nodes of the entire enterprise network, and isable to process application data output by heterogeneous computingplatforms and applications. As a result, the enterprise business processmanagement system may provide a variety of integrated views of datapresent throughout the enterprise. Such views may range from dataassociated with the total enterprise, to individual divisions orbusiness functions/business units, down to individuals.

For example, an embodiment of the enterprise business process managementsystem may be directed to biometric and homeland security applicationssuch as, but not limited to, defining, building and executing businessprocesses that include functions from business applications involvingfingerprint analysis, retinal imaging/scanning, voice identification,and image matching and comparison. In a particular example of such abusiness process, an employee of a company may be required to pass afingerprint identification scan in order to enter a company facility.When the employee places their fingerprint on a fingerprint pad orscanner, data representing the unique fingerprint scan may be sent to aprocess maintained by the enterprise business process management system.This process may include, for example, comparing the scanned fingerprintdata to a set of valid fingerprints using one or more functions fromdifferent fingerprint software matching tools that attempt to validatethe employee against the company employee fingerprint database. If theemployee is validated as an employee then a signal may be sent from theenterprise business process management system to an access controldevice of the door so that the door will unlock and allow the employeeingress access.

In another example of such a business process, photographic imaging datamay be input to a multiple step business process that attempts to matchthe photographic imaging data against multiple image databases to searchfor matching features. If a match is found, then a signal may be sent toanother process maintained by the enterprise business process managementsystem to output the image coordinates to a targeting or reportingsystem.

In another example, an embodiment of the enterprise business processmanagement system may be directed to compliance assurance such as, forexample, business compliance with applicable governmental regulations.Such applications are myriad. One example in particular may be abusiness process directed to ensuring that a healthcare enterpriseoperates in conformance with government mandated rules and regulationssuch as, for example, the Health Insurance Portability andAccountability Act of 1996 (“HIPAA”). In a particular example of such abusiness process, business rules applying HIPAA requirements may bemaintained in the function library, and a business process defined andexecuted that includes a series of business rules that must be appliedto particular patient information based upon government HIPAArequirements. In an embodiment, this process may be a multiple stepprocess with each step representing a different HIPAA requirement. Thisarrangement may provide for easy modification of such rules based uponchanging government requirements. In other words, after the roads to thebusiness applications for HIPAA compliance have been established, thecorresponding functions used to represent the requirements as processsteps may be modified as described herein using, for example, theinterface module process designer. In this way, new changes toregulations affecting a business may be accommodated with minimal impactto the business process.

As another example, an embodiment of the enterprise business processmanagement system may be directed to ensuring that government dataquality regulations are met for a data set. For example, data concerningchild welfare provided to the federal government may be required tocomply to a specified data accuracy, such as greater than 90% accuracy.

As another example, an embodiment of the enterprise business processmanagement system may be directed to tax assignment applications suchas, but not limited to, defining, building and executing businessprocesses that include functions from business applications involvinggeographic coding software and tax assignment software. In a particularexample of such a business process, an organization may need tocorrectly assign the appropriate tax to their client's bills during thebilling process. Incorrect tax assignment during the billing process mayresult in lost customers. Therefore, in an embodiment, a businessprocess may be created and executed (or, alternatively, a sequence ofprocess steps in a billing process) in which customer information, suchas address information, is checked for accuracy by multiple functionsfrom different tax assignment business applications (e.g., softwarepackages) prior to final processing and mailing of bills to customers.The results of the functions may then, for example, be compared againsteach other and based on those results a correct tax could then beassigned. Furthermore, after the correct tax is determined, the correcttax assignment and the customer identifier may be sent as input intoanother business process which may, for example, receive as input a taxassignment and a customer identifier, and then perform multiple steps inwhich each step would perform an SQL query against different databases.In an embodiment, each step may perform a data store lookup of thecustomer via the customer identifier and then update that customer's taxassignment so that the customer has the same tax assignment acrossmultiple data stores.

As another example, an embodiment of the enterprise business processmanagement system may be directed to product comparison applicationssuch as, but not limited to, defining, building and executing businessprocesses that include functions from business applications involvingaddress validation. In a particular example of such a business process,a business process may be created and executed which receives as inputan individual's address, and then performs a multiple step process. Inan embodiment, each step in the business process may include, forexample, a different software vendor's address coder. Each step mayattempt to receive as input the address and then validate that addressagainst its own postal database. In an embodiment, a comparison of eachvendors capabilities may then be performed and statistics could becreated to see exactly which product performs the best under certaindata conditions. FIG. 38 illustrates the comparison business process inaccordance with an embodiment.

More generally, if an organization is trying to decide which softwareapplication or vendor provides the best functionality, then thoseproducts may be integrated under the enterprise business processmanagement system and comparatively tested. Furthermore, any businessprocess that compares different software vendors API calls can beincluded in such a process.

As another example, an embodiment of the enterprise business processmanagement system may be directed to data mapping or transformationapplications such as, but not limited to, defining, building andexecuting business processes that include functions from businessapplications involving data store transformation software. In aparticular example of such a business process, a business process couldbe created and executed in which there the input data is received in afirst format associated with one data store (e.g., first database) andthe output data is provided in another data store (e.g., seconddatabase) format. In an embodiment, each process step may be a mappingfrom one field type to another, for example.

Finally, as another example, an embodiment of the enterprise businessprocess management system may be directed to software-based mappingapplications such as, but not limited to, defining, building andexecuting business processes that include functions from businessapplications involving information matching and database retrievalsoftware. In a particular example of such a business process, a businessprocess may include information matching and data store lookups forinformation related to call center operations. In particular, a callcenter operator may take a call from a customer in which the customerprovides the call center operator name and address information. The callcenter operator may input the information using, for example, andinteractive page, and then initiate a search request. The search requestmay cause the name and address information to be sent to a businessprocess maintained by the enterprise business process management systemthat may perform, for example, the following steps:

-   -   a. Standardize the Name and Address Data    -   b. Create a Match Key    -   c. Perform a series of database lookups using the match Key        created in step b    -   d. Each database lookup would return back some information that        would be used to build a temporary record    -   e. After all of the database lookups have been performed the        Output would be sent back the Call Center Reps screen.

Users of the enterprise business process management system, includingmanagement and executive users, may be provided different levels ofvisibility into enterprise-level issues such as, but not limited to,data quality issues, so that appropriate corrective action may be taken.In at least one embodiment, the enterprise business process managementsystem may automatically make corrections to incorrect or errored databased on a trusted source of data. Because of the integrated viewprovided by the enterprise business process management system of thepresent invention, the shortcomings of vendor-specific approaches suchas, for example, application-specific data checking processes, areminimized. In addition, total acquisition costs for data quality tools,for example, may be minimized for the enterprise through use of theintegrated approach described herein, because the need to acquire andmaintain many individual independent data quality applications isreduced.

Furthermore, in at least one embodiment, the business process server maybe further configured to select and execute a set of preferredfunctions, wherein each preferred function is obtained from one ofmultiple different business applications. The business process servermay select one function from among multiple similar functions providedby business applications based on, for example, a selection heuristic.An example of such a selection heuristic may be the percentage of errorsdetected by a function in a comparison of multiple similar functionsapplied to a given set of business application output data. Each of thebusiness applications may or may not be products from different vendors.Alternatively, the function selection criteria may be specified by auser via an interactive page of the interface module. In this way, theenterprise business process management system may select a set ofpreferred or “best of breed” functions from among those offered bydifferent business applications.

It is also contemplated that a plurality of enterprise business processmanagement systems 100 may be managed by another enterprise businessprocess management system 100. This management system, which is depictedschematically in FIG. 40, will be designated as a global managementsystem 4000 to distinguish it from the business process managementsystem 100 described hereinbefore. It should be understood, however,that the functionality of the global management system 4000 is similarto the functionality of the business process management system 100. Infact, as will be detailed below, the global management system 4000 maybe provided with all of the functionality of each of the individualbusiness process management systems 100 to which it is connected. If notprovided with all of the functionality of the individual businessprocess management systems 100 to which it is connected, it iscontemplated that the global management system 4000 will have at leastsome of the functionality of each of the individual enterprise businessmanagement systems 100 to which it is connected.

As illustrated in FIG. 40, the global management system 4000 connects toan enterprise business process management system 100 and to a clientserver 4002. The communicative connections to the client server 4002 andthe enterprise business process server 101 may be, for example, via aLAN, WAN, intranet, the Internet, telephone lines, or wirelesscommunication, as would be appreciated by those skilled in the art. Asdiscussed above, the actual manner in which the components communicatewith one another is not critical to the operation of the presentinvention and any type of communication link may be used.

In the schematic diagram provided by FIG. 40, the global managementsystem 4000 is shown connected to a single enterprise business processmanagement system 100. This simplified diagram illustrates the basicinteraction between the global management system 4000 and the localbusiness process management system 100. It should be noted, however,that it would be unlikely for a global management system 4000 to beconnected to a single enterprise business management system 100, becausethe two systems would be redundant.

However, the present invention contemplates that one global managementsystem 4000 may be connected to only one enterprise business managementsystem 100. As discussed in greater detail below, it is contemplatedthat a global management system 4000 may be connected to a singleenterprise business process management system 100 for the purpose ofprotecting the security of the data, executables and applicationsresident in the local management system 100. Other advantages are alsopossible through this arrangement, as would be appreciated by thoseskilled in the art.

For definitional purposes in the discussion that follows, the enterprisebusiness process management system 100 will be referred to as the “localmanagement system” 100. The reason for this is straightforward. It iscontemplated that the enterprise business process management system 100will be installed at a local client location. The local location couldbe an individual business unit of a company or a department of a local,state, or federal government. It is contemplated that the localmanagement system 100 may be connected to a number of additional servers102, 103, 104, 105 and/or mainframes 108 as discussed in connection withFIG. 1, for example. Where the enterprise business process managementsystem 100 is resident at a local location, it may be desirable for thatlocal management system 100 to be connected to the global managementsystem 4000, which is expected to be resident at a higher level in theorganization.

For example, taking the U.S. Federal Government as an example, it iscontemplated that local management systems 100 may be installed in eachof the following departments: the United States Patent and TrademarkOffice, the Department of Commerce, the Federal Aviation Administration,the Federal Communications Commission, the Department of Defense, etc.As may be appreciated by those skilled in the art, the number ofpossible permutations is considerably large. The local managementsystems 100 are contemplated to operate in one or more of the mannersdiscussed above.

In the case of the United States Federal Government, there may be anadditional need to cross-link each of the local management systems 100through the global management system 4000 so that functionalitiesresident in the individual governmental branches may be shared withother branches of government.

This same structure may be overlaid onto a corporate entity. In thecorporate context, the local management system 100 may be resident in acorporate division that manufactures a particular product or group ofproducts. Other local systems 100 may also be resident in othercorporate subsidiaries that manufacture different products or lines ofproducts. The local management systems 100 may be used in the mannerdescribed above. The global management system 4000 may be resident atthe head office level, which oversees each of the individualsubsidiaries or business units and provide a coordinating functionbetween the local management systems 100.

Referring back to FIG. 40, the enterprise business management server 101is connected directly to the global management system 4000 via a one-waycommunications link 4004. As discussed above, and as would be apparentto those skilled in the art, the communications link may be any type ofwired or wireless link. The communications link 4004 from the localmanagement server 101 provides information to the global managementsystem 4000. It is contemplated, however, that information from theglobal management system 4000 will not travel directly back to the localmanagement server 101 via the communications link 4004. Instead,information and instructions from the global management system 4000 areprovided to the local management server 101 indirectly through a two-waycommunications link 4006 to a client server 4002, which is also locallyresident in the entity sub-unit. In turn, the client server 4002communicates, through a two-way communications link 4008 to the localmanagement server 101. With this arrangement, it is possible to protectthe operation of the local management system 100 from corruption thatmay be present in the global management system 400 and vice versa.

Typically, the client server 4002 will be provided with a securitysystem, also known as a “firewall.” By connecting the local managementserver 101 with the global management system 4000 through the clientserver 4002, the firewall resident on the client server 4002 willprotect the communications from the global management system 4000 sothat the local management system 100 cannot be infected with viruses,etc., from the global management system 4000. In addition, bycommunicating through the client server 4002, the individual businessprocesses 2025 and functions 2035 that are resident locally may beprotected locally. In one example, by communicating through the clientserver 4002, the data, executables and applications that are resident onthe local management server 100 are kept secure. Similarly protected arethe information, executables and applications resident on any of theother servers 102, 103, 104, 105 or mainframes 108 to which the clientserver 4002 is connected. Moreover, the data located in data stores 106or flat files 107, which are also connected to the local managementserver 100 may be protected as well.

FIG. 41 illustrates the operation of a global management system 4100when connected to two local management servers, which are labeled 4102and 4104 for convenience. As indicated above, the global managementsystem 4100 is basically an enterprise business management system 100that has been connected to a plurality of other enterprise businessmanagement systems 4102, 4104, except that the global management system4100 sends and receives information and instructions to and from thelocal management systems 4102, 4104 via a client server 4002. The globalmanagement system 4100 encompasses an enterprise manager interface 4106and an enterprise manager server 4108. As illustrated, the enterprisemanager interface 4106 and the enterprise manager server 4108 areconnected by a two-way communications link 4110.

The enterprise manager server 4108 is connected via two-waycommunications links 4112, 4114 the local client servers 4116, 4118. Thelocal client servers 4116, 4118, in turn, interact with the localmanagement servers 4102, 4104 through two-way communications links 4120,4122. The local management servers 4102, 4104 can send information andinstructions to the enterprise manager server 4108 via one-waycommunications links 4124, 4126. In addition, the local managementservers 4102, 4104 can communicate with one another via a two-waycommunications link 4128. This communications link 4128 permits thelocal management servers 4102, 4104 to cooperate with one another, atthe direction of the global management system 4100, to carry outprocesses that neither of the local management servers 4102, 4104 couldcarry out alone.

In the example provided in FIG. 41, the local management server 4102,which is labeled “enterprise business process server #1,” is aLinux®-based system 4130. The local management business server 4104,which is labeled “enterprise business process server #2” is aWindows®-based system 4132. Despite the fact that the two systemsfunction with different operating systems, and possibly differenthardware, they communicate with one another through the local managementservers 4102, 4104 and the global management system 4100 to cooperate asinstructed. As also shown in FIG. 41, the two local management servers4102, 4104 have access to different libraries containing differentprocesses 2025, functions 2035 and links 2045, which have been discussedabove.

A user 4134 may access the processes 2025, functions 2035, and links2045 in each of the local management servers 4102, 4104 via a two-waycommunications link 4136 to the global management system 4100. However,as discussed above, users may access the local management servers 4102,4104 as well. When the local management servers 4102, 4104 are connectedto the global management system 4100, users at the local level may alsoaccess the processes 2025, functions 2035 and links 2045 of other localmanagement servers.

FIG. 42 illustrates schematically the global enterprise processmanagement system 4200 that is created when global management system4100 is connected to two local management systems 4202, 4204. Asdiscussed in connection with FIG. 40 and 41, the global managementsystem 4100 is connected via a two-way communications link 4206 with thelocal management system 4202. Similarly, the global management system4100 is connected to the local management system 4204 via anothertwo-way communications link 4208. The two local management systems 4202,4204 are connected to one another via a third two-way communicationslink 4210.

As should be appreciated, FIG. 42 is a simplified schematic of theoverall universal management system 4200 that was discussed inconnection with FIGS. 40 and 41. The schematic has been simplified tofacilitate a discussion of how the three management systems 4100, 4202,4204 cooperate with one another.

As shown in FIG. 42, the first local management system 4202, labeled“Local Management System #1,” has a library 2005 of processes 2025resident therein. In this simplified example, there are three residentprocesses 2025: Process A, Process B, and Process C. Similarly, thesecond local management system 4204, which is labeled “Local ManagementSystem #2,” has a library 2005 that includes three processes 2025:Process D, Process E, and Process F. For purposes of this example, whilethe libraries 2005 each include three processes 2025, the libraries 2005could include a large number of processes 2025, functions 2035, andlinks or roads 2045.

As discussed above, in one embodiment of the invention, a userinteracting with the first local management system 4202, wanting todesign a business process combining individual processes A and B,interacts with the process designer interactive display 2000 to createand modify process steps 2025 which make up a business process. Theprocess interactive display 2000 permits the user to design the businessprocess via drop and drag functionality. The interface module 304 thenassembles (or builds) a sequence of instructions implementing theinterface module process designer defined process step 2025 in a seriesof build up steps using a number of build files. As may be appreciated,the process designer cannot access any of the processes D, E, or F thatare present on the second local management system 4204 unless thoseprocesses are moved physically to the first local management system4202. Therefore, the designer is limited to the development of businessprocesses that combine only those discrete processes 2025 residentthereon. With the global management system 4100 connected to the twolocal management systems 4202, 4204, however, it is possible to buildbusiness process that combine all of processes A-F, in any manner thatthe user selects.

In operation, the global management system 4200 functions so thatselected processes 2025, functions 2035, and links or roads 2045 may beuploaded from each of the local management servers 4202, 4204 to theglobal management system 4100, or the processes 2025, functions 2035,and links or roads 2045 may be transferred to the local managementservers 4202, 4204 from the global management system 4100.Alternatively, all of the processes 2025, functions 2035, and links orroads 2045 may either be uploaded to the global management system 4100from a local management system, or transferred from the globalmanagement system 4200 to the local management server 100. In such acase, the global management system 4100 creates a library that containsa combined list of all of the processes A-F that are present on the twolocal management servers 4202, 4204.

It should be noted that the data, executables and applicationsunderlying the individual processes 2025, functions 2035, and links (orroads) 2045 do not have to be transferred to the global managementsystem 4100. All that needs to be transmitted is the information, forexample in XML format, that describes to the global management system4100 process 2025, function 2035, or road 2045 located on the localmanagement system 4202, 4204.

When a user accesses the library 2005 in the global management system4100, the user gains access to all of the processes 2025, functions2035, and links or roads 2045 (hereinafter referred to collectively as“tools”) that have been uploaded thereto. This collection is referred toas the “toolkit.” Since the toolkit combines the functions 2035 frommultiple different local management systems 4202, 4204, the toolkit inthe global management system 4100 is referred to as an “integratedtoolkit.” The user may then design a business process using one or moreof the functions 2035 in the integrated toolkit in the same manner asthe user would design a business process using only the functions 2035available on a local management system 4202, 4204.

Next, the operation of the universal management system 4200 will bedescribed. In a first example, the user designs a business process thatincorporates the following process steps in the following order: ProcessA→Process B→Process C→Process D→Process E→Process F. The globalmanagement server 4100 assists the development of the business processin the manner described above. The process would be carried out in thefollowing manner. First, instructions would be sent to both localmanagement systems 4202, 4204 to assemble the steps in the orderpresented by the user. The first local management system 4202 wouldcompile a set of instructions that permit data to be manipulated throughthe three steps A→B→C. The second local management system 4204 wouldcompile a set of instructions that manipulate the data through the threesteps D→E→F. Once compiled, the steps A→B→C on the first localmanagement system 4202 are, for all intents and purposes, considered asa single process step. The process D→E→F compiled by the second localmanagement system 4204 also appears as a single process step. Once theportions of the business process are prepared, the business process maybe performed.

Data from a data source is first sent to the input of the first processstep A→B→C, which generates an output set of data. That output data isthen sent to the second local management server 4204, which performs thesecond process step D→E→F on the data to create a final data set. Thatdata set is then returned to the user.

In this example, the methodology is fairly straight forward because thedata passes through the portion of the process on the first localmanagement system 4202 before being passed to the second localmanagement system 4204 for final processing. While this is one possibleroute for the data, the present invention also contemplates thedevelopment of considerably more complex business processes where thedata sets are passed back and forth, through the communication link4210, multiple times before the process is completed. For example, ifthe user were to design a business process with steps in the followingorder, A→B→D→C→E→F, the data would pass back and forth between the twolocal management systems 4202, 4204 three times.

As may be apparent from the description provided above, the globalmanagement system 4100 does not receive any portion of the code that isresident on any of the local management servers 4202, 4204. Instead, theglobal management system 4100 receives the XML files that provide theinformation necessary to develop the business process desired. Theglobal management system 4100 communicates with the local managementsystems 4202, 4204 that actually builds and runs the code associatedwith those instructions in the manner described above.

The operation of the universal management system 4200 described above isa “dynamic” system. For purposes of the present discussion, this meansthat the universal management system 4200 will change over time. Forexample, the universal management system 4200 may be connected toadditional local management systems (akin to the local managementsystems 4204 and 4204). When new local management systems are added, notonly may the geographical diversity of the entire system be changed, butalso the technological diversity of the universal management system 4200also may be changed. For example, the newly added local managementsystem may operate on different hardware and operate via differentsoftware than others of the local management systems, such as 4202 and4204.

As new local management systems 4202, 4204 are added to the universalmanagement system 4200, the operation of the universal management system4200 understandably will change. Not only does the addition of a newlocal management system increase the total computing power and resourcesof the universal management system 4200, but the universal managementsystem 4200 may gain access to additional functionality (e.g.,information, executables, and applications) that were not previouslyavailable to the universal management system 4200. Accordingly, when anew local management system is added to the universal management system4200, the operation of the universal management system 4200 may bealtered, especially since the universal management system 4200 permitsthe development of tools, processes, functions, etc. based on availabletechnology, information, executables, applications, functions, tools,codes, and other aspects of both hardware and software.

Another aspect of the invention that should be mentioned is that theuniversal management system 4200 may operate differently, even ifrequired to perform the same business process time and time again. Thisfunctionality is also a part of the dynamic operation of the universalmanagement system 4200. Many factors may contribute to the dynamicoperation of the universal management system 4200. One factor may be theavailable computing resources. Assume that a request is made to executea business process, which will be called Process 1. When executed thefirst time, the universal management system 4200 will select those localmanagement systems (such as 4202 and 4204) that may assist with theexecution of Process 1. Upon a second request to execute Process 1, thesame resources may not be available to the universal management system4200, which may then require reliance on different local managementsystems that are available to execute Process 1.

A further aspect of the invention, as may be apparent from thediscussion above, lies in the virtual operation of the universalmanagement system 4200 (or any of its subcomponents). The universalmanagement system 4200 may download the business process, for exampleProcess 1, to a number of local management systems (such as 4202 and4204) for execution of the business process. The instructions, however,do not need to be located on any of the hard drives (or stored in anymanner, for that matter) on any of the local management systems. Theinstructions and the data may be supplied by the universal managementsystem 4200 to the local management systems so that the local managementsystems may execute the business process and return the result to theuniversal management system 4200. Upon completion of the executables inthe business process, the instructions and data can be deleted from theactive memories of the local management systems so that the localmanagement systems are freed for further operations, processes, andexecutables, for example.

While the invention has been described with reference to the certainillustrated embodiments, the words which have been used herein are wordsof description, rather than words of limitation. Changes may be made,within the purview of the appended claims, without departing from thescope and spirit of the invention in its aspects. Although the inventionhas been described herein with reference to particular structures, acts,and materials, the invention is not to be limited to the particularsdisclosed, but rather extends to all equivalent structures, acts, andmaterials, such as are within the scope of the claims thereto.

1. A global enterprise business process management system, comprising: afirst enterprise business process server capable of receiving data fromat least one client; at least one second enterprise business processserver in communication with the first enterprise business processserver, the second enterprise business process server being capable ofreceiving data from at least one other client; at least one first routeraccessible by the first enterprise business process server; at least onefirst business process accessible by the at least one first router,wherein the first enterprise business process server is configured toaccess the at least one first business process via the first router, toexecute the at least one first business process on at least a portion ofthe client data, and to generate business process output data as afunction of the at least one first business process; a first interfaceaccessible by the first enterprise business process server, wherein thefirst interface operates with the enterprise business process server tooutput a process designer interactive page, wherein the process designerinteractive page is configured to accept instructions concerning the atleast one first business process, to generate process information data,and to provide the process information data to the first enterprisebusiness process server, wherein the first enterprise business processserver builds an instruction set for the first business process basedupon the process information data, and wherein the first enterprisebusiness process server has access to at least some of businessprocesses available on the second enterprise business process server. 2.The global enterprise business process management system of claim 1,wherein the first and second enterprise business process servers are indisparate geographic locations.
 3. The global enterprise businessprocess management system of claim 1, wherein the first and secondenterprise business process servers operate via different operatingsystems.
 4. The global enterprise business process management system ofclaim 3, wherein the first enterprise business process server operatesvia a Linux-based operating system.
 5. The global enterprise managementsystem of claim 4, wherein the second enterprise business process serveroperates via a Windows-based operating system.
 6. The global enterprisebusiness process management system of claim 1, further comprising: atleast one second router accessible by the second enterprise businessprocess server; at least one second business process accessible by theat least one second router, wherein the second enterprise businessprocess server is configured to access the at least one second businessprocess via the second router, to execute the at least one secondbusiness process on at least a portion of the client data, and togenerate business process output data as a function of the at least onesecond business process; a second interface accessible by the secondenterprise business process server, wherein the second interfaceoperates with the enterprise business process server to output a processdesigner interactive page, wherein the process designer interactive pageis configured to accept instructions concerning the at least one secondbusiness process, to generate process information data, and to providethe process information data to the second enterprise business processserver, and wherein the second enterprise business process server buildsan instruction set for the second business process based upon theprocess information data.
 7. The global enterprise business processmanagement system of claim 1, wherein the at least one first businessprocess is executable on at least one of the first and second enterprisebusiness process servers.
 8. The global enterprise business processmanagement system of claim 1, wherein at least one of the first andsecond enterprise business process servers dynamically establishes theexecution sequence of the at least one business process on at least oneof the first and second enterprise business process servers.
 9. Theglobal enterprise business process management system of claim 8, whereinthe decision of how the at least one business process is executedchanges based upon priority of at least one of network traffic,operating system capacity, and the availability of at least one of thefirst and second enterprise business process servers to execute the atleast one first business process.
 10. The global enterprise businessprocess management system of claim 1, wherein the at least one firstbusiness process may be distributed to the second enterprise businessprocess server from the first enterprise business process server. 11.The global enterprise business process management system of claim 1,wherein the execution of the at least one first business process may bemonitored.
 12. A global enterprise business process management system,comprising: a plurality of enterprise business process servers capableof receiving data from at least one client; a router accessible by atleast one of the enterprise business process servers; and a businessprocess accessible by the router, wherein one of the enterprise businessprocess servers is configured to access the business process via therouter, to execute the business process on at least a portion of theclient data, and to generate business process output data as a functionof the business process.
 13. The global enterprise business processmanagement system of claim 12, further comprising: an interfaceaccessible by one of the plurality of enterprise business processservers, wherein the interface operates with the enterprise businessprocess server to output a process designer interactive page, whereinthe process designer interactive page is configured to acceptinstructions concerning the business process, to generate processinformation data, and to provide the process information data to theenterprise business process server, wherein the enterprise businessprocess server builds an instruction set for the business process basedupon the process information data, and wherein the enterprise businessprocess server has access to at least some of business processesavailable on others of the plurality of enterprise business processservers.
 14. The global enterprise business process management system ofclaim 12, wherein the enterprise business process is loaded dynamicallyfrom one of the plurality of enterprise business process servers into atleast one other of the enterprise business process servers.
 15. Theglobal enterprise business process management system of claim 14,wherein, after providing the process information data, the businessprocess is unloaded from the at least one of the plurality of enterprisebusiness process servers.
 16. The global enterprise business processmanagement system of claim 12, wherein at least one function is loadeddynamically from one of the plurality of enterprise business processservers into at least one other of the enterprise business processservers.
 17. The global enterprise business process management system ofclaim 16, wherein, after providing the process information data, the atleast one function is unloaded from the at least one of the plurality ofenterprise business process servers.
 18. The global enterprise businessprocess management system of claim 12, wherein data may be convertedfrom one format to another depending upon the format required by theenterprise business process server processing the data.
 19. The globalenterprise business process management system of claim 18, wherein thebusiness process converts the data from format to another.
 20. Theglobal enterprise business process management system of claim 18,wherein a function converts the data from format to another.